# Algorithms in Java from Prim's MST to Dijkstra SPT

I am following the code of the Algorithms in Java, Part 5: Graph Algorithms, 3rd Edition book and in page 294 it describes that we can have the classic Dijkstra algorithm by modifying Prim's Minimum Spanning Tree (MST) algorithm (which I tested and works fine) in the following way: change the priority assignment from `P = e->wt()` the edge weight to `P = wt[v] + e->wt()` the distance from the source to the edge’s destination. The problem is that when I make the change the condition that follows never evaluates to `true` and it is understandably so. `wt` is a double array initialized to e.g. `Double.MAX_VALUE` therefore no matter what `v` and `w` are, this condition will never hold (assuming non negative weights):

``````P = wt[v] + e->wt();
if (P < wt[w]) { // this can never happen ... bug?
// ...
}
``````

I checked the web site of the book and see no errata.

This is my self contained version of the code with a runnable Main with the test case from the book:

• added initialization line `wt[getSource().index] = 0.0;` following feedback from one of the answers. The source vertex belongs to the SPT with distance zero.

``````import java.util.*;

//=============================================================
// members
//=============================================================
private static class Edge {
int source;
int target;
double weight;
};
private static class Vertex {
int index;
String name;
List<Edge> edges = new ArrayList<Edge>();
public Vertex(int index, String name) {
this.index = index;
this.name = name;
}
};
private static final int UNDEFINED = -1;
private int edgesCount = 0;
private final Vertex[] vertices;
private final boolean digraph;
private int orderCount;

//=============================================================
// public
//=============================================================
public AdjacencyList(int verticesCount, boolean digraph) {
this.vertices = new Vertex[verticesCount];
this.digraph = digraph;
}

public Vertex createVertex(int index) {
return createVertex(index, String.valueOf(index));
}

public Vertex createVertex(int index, String name) {
Vertex vertex = new Vertex(index, name);
vertex.index = index;
vertex.name = name;
vertices[index] = vertex;

return vertex;
}

public Edge addEdge(int begin, int end, double weight) {
}

public Edge addEdge(Vertex begin, Vertex end, double weight) {
edgesCount++;
Edge edge   = new Edge();
edge.source = begin.index;
edge.target = end.index;
edge.weight = weight;
if (!digraph) {
Edge reverse = new Edge();
reverse.source = end.index;
reverse.target = begin.index;
reverse.weight = edge.weight;
}
return edge;
}

// inefficient find edge O(V)
public Edge findEdge(int begin, int end) {
Edge result = null;
Vertex vertex = vertices[begin];
for (Edge edge : adjacency) {
if (edge.target == end) {
result = edge;
break;
}
}
return result;
}

// inefficient remove edge O(V)
public void removeEdge(int begin, int end) {
edgesCount--;
removeOneEdge(begin, end);
if (!digraph) {
removeOneEdge(end, begin);
}
}

public final Vertex[] getVertices() {
return vertices;
}

public int getVerticesCount() {
return vertices.length;
}

public int getEdgesCount() {
return edgesCount;
}

public Vertex getSource() {
return vertices[0];
}

public Vertex getSink() {
return vertices[vertices.length - 1];
}

public void dijkstra() {
int verticesCount = getVerticesCount();
double[] wt = new double[verticesCount];
for (int i = 0; i < wt.length; i++) {
wt[i] = Double.MAX_VALUE;
}
wt[getSource().index] = 0.0;
Edge[] fr  = new Edge[verticesCount];
Edge[] mst = new Edge[verticesCount];
int min = -1;
Edge edge = null;
for (int v = 0; min != 0; v = min) {
min = 0;
for (int w = 1; w < verticesCount; w++) {
if (mst[w] == null) {
double P = 0.0;
edge = findEdge(v, w);
if (edge != null) {
if ((P = wt[v] + edge.weight) < wt[w]) {
wt[w] = P;
fr[w] = edge;
}
}

if (wt[w] < wt[min]) {
min = w;
}
}
}

if (min != 0) {
mst[min] = fr[min];
}
}

for (int v = 0; v < verticesCount; v++) {
if (mst[v] != null) {
System.out.print(mst[v].source + "->" + mst[v].target + " ");
}
}
}

public void pushRelabel() {
// TODO
}

//=============================================================
// private
//=============================================================

private void removeOneEdge(int begin, int end) {
Vertex beginVertex = vertices[begin];
int position = -1;
for (int i = 0; i < adjacency.size(); i++) {
position = i;
break;
}
}
if (position != -1) {
}
}

int numberOfVertices = 6;
boolean directed = true;
for (int i = 0; i < graph.getVerticesCount(); i++) {
graph.createVertex(i);
}
return graph;
}

/**
* Test main
*
* @param args
*/
public static void main(String[] args) {
// build the graph and test dijkstra shortest path
// expected:
System.out.println("\n\n*** testing dijkstra shortest path");
directedDijkstra.dijkstra();
}
}
``````
-

You get it wrong, since v != w, wt[v] + e->wt() can be smaller than wt[w]. The actual error is that you need to set `wt[source] = 0` (dijkstra is single-source shortest path, you need a source!) ! About the book: if they forgot that part, their bad :-P
OK I checked what happens, the condition `if (wt[w] < wt[min])` is never true, because `wt[min]` when `min == source` is zero. –  Giovanni Azua Jan 19 '13 at 14:26